DE2460218A1 - LINEAR DATA INPUT CONVERTER - Google Patents

Description

19 Ε) Γ7197t

SIEMENS AKTIENG-ESSLLoCHAFiI! . Munich 2, the '~ "

Berlin and Munich Wittelsbacherplatz 2

YPA- 74/7248

Linear data input converter

Linear data input converter for holographic data storage, consisting of a laser transmitter, a beam splitter, the the beam of the laser transmitter into an object beam and a Splits reference beam from one in the object beam path arranged acousto-optical modulator, which spatially modulates the object beam in the modulator with information fed in, and from a hologram plate onto which the object beam and the Reference beam is steered »

Linear acousto-optic data input transducers are for the purpose the fast data entry in holographic memories from one in Proc. of the electro-optical system. Design Conf., New York, Sept. 18-20, 1973, pp. 90-101 known article. The Piaζo- ¥ andler of an acousto-optical modulator mentioned there records the information to be stored serially in the form of a pulse-modulated high-frequency signal. A correspondingly modulated high-frequency ultrasonic wave passes through the modulator at the speed of sound. As soon as the entire modulated sound wave fills the aperture of the modulator, if this is illuminated with an extremely short laser pulse, during which time the sound wave practically does not move. The spatially modulated first optical diffraction order is applied to the part to be described by a lens of a storage tape focused.

However, this data converter has the disadvantage that for lighting a nanosecond trap pulse laser is required.

The object of the invention is to provide a fast linear data input converter specify that can be illuminated with continuous wave lasers and operated with low control power.

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This object is achieved according to the invention in that the modulator consists of a first and a second acousto-optical light deflector, the sound waves of which run perpendicular to one another _; and that the signal inputs of both light deflectors are connected via a summing circuit to a chain of high-frequency oscillators which can be switched on independently of one another or can be analogously modulated.

The two acousto-optic light deflectors are using the same High frequency signal driven with several different frequencies. The two sound media are therefore

of signals

waves generated by adding-x-many frequencies will. An irradiated light wave is therefore deflected in a "multitude of directions. The movement of the acoustic Diffraction grating also causes a shift in the light frequencies of the emitted light beams at precisely these control frequencies. This results in the activation of an acousto-optical Light deflector with η oscillators η light rays with η different Light frequencies.

When controlling the second acousto-optical light deflector with the already diffracted η light rays in a direction perpendicular to the first direction become the same signal deflected in the second direction «This creates a two-dimensional one Light point grid, whereby all points have different light frequencies.

With the reference beam is capable of interference because of the low Line width of the mostly used gas lasers (order of magnitude 1 KHz) only light with the same frequency as that of the reference beam, that is, light which, when the light deflector is controlled with the frequencies f.- in the first light deflector, enters the positive first diffraction order and in the second light deflector in the negative first diffraction order or vice versa will.

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All points of light of the two-dimensional grid that are in the are the main diagonals directed towards the zero order, meet the specified condition, i.e. their light frequencies are the same and also agree with the light frequency of the laser: The double shift of the light frequencies the second light deflector made this point complete compensated.

The directions of the beam are generated by the high-frequency oscillators on or off. Bit reference patterns are recorded on the hologram plate, which are used during the reconstruction result in an inclined linear chain of points, with empty spaces depending on the expensive signals (oscillator switched off) and points of light (oscillator switched on) arise.

By using two deflectors, the resolution of the Data input converter because of the larger distance between the The diagonal of the light point grid lies around the light points opposite a data input converter with only one light deflector a factor |? greater. One such linear data input converter has a data rate between 10 and 100 M blt / s. The ZaML dier switchable high-frequency oscillators can be up to be over 200. In addition, the data input transducer can be constructed from commercially available acousto-optic modulators will.

A compact linear data input converter then results when the first and the second acoustic ο optical light deflector closed is assembled into a single light deflector cell. For this are! two electric transducers on two perpendicular to each other Surfaces of the sound mediuras arranged. The SB generate two crossing sound waves, when activated the belien sound transducer with the same high frequency signal an irradiated light wave in the same direction deflected as if by two acousto-optical © arranged one behind the other Light deflector.

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Commercially available, powerful gas lasers with line widths of the order of magnitude can be used as laser transmitters of 1 KHz can be used.

To hide all except those on the diagonal of the grid of points A diaphragm is arranged in particular in the beam path behind the two modulators.

With the data input converter, both analog and digital information can in principle be represented optically, since the light beam directions can not only be switched on and off independently of one another, but can also be modulated analogously, It is also used for the holographic recording of analog information suitable.

Details of the invention are explained using exemplary embodiments in the description of the figures.

Figure 1 shows a linear acousto-optical according to the invention Data input converter,

Figure 2 is a circuit diagram for the electronic control of the data converter,

FIG. 3 shows a compact light deflector cell, FIG. 4 shows a light point grid and

FIG. 5 the reconstruction of a hologram.

In the figure 1, an acousto-optical data input converter is shown with a modulator, which consists of two in a row arranged acousto-optic light deflectors. A light beam 2 is emitted by a gas laser 1 and through a beam splitter 3 into an object beam 4 and a Reference beam 5 split. The object beam 4 runs into the sound medium of an acousto-optical light deflector 6, which Via a sound transducer 7 at the same time with several equidistant ones Oscillator frequencies e.g. between 50 and 90 MHz is controlled.

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The object beam 4 is deflected in several directions by the sound wave running in the sound medium. This distracted Light beams are in the sound medium of a second acousto-optical light deflector 8 with a sound transducer 9 introduced. In this sound medium, the sound wave runs perpendicular to the direction of that in the first sound medium ongoing. Sound wave. There are now again distractions in several directions. The one from the second acousto-optic Light beams emerging from light deflectors 8 pass through a light point grid according to FIG. 4 Lens 10. Because of the different drive frequencies of the acasto-optical light deflectors 6 and 8, the light rays Not all of them can have different light frequencies Light rays after their deflection by the mirror 11 on the hologram plate 12 with the reference beam 5, which passes through the Mirror 13 is directed to the hologram plate 12, interfere. Details are explained with reference to FIGS. 4 and 5.

As mentioned at the beginning, the two acousto-optical light deflectors are used 6 and 8 driven by the same signal.

The associated electronic control circuit shows'die Figure 2.

A chain of η oscillators with frequencies f *, f ₂ , ..., f _{n is} shown here. These oscillators 14 are connected to η switching gates 16 together with the shift register 15. The output signals of the η high-frequency oscillators 14 are added by a summing circuit 17 and fed to the sound transducers 7 and 9. The high-frequency oscillators 14 can be modulated independently of one another. By switching certain oscillators on and off, the associated beams can be switched on and off.

A compensation for the generally frequency-dependent deflection efficiency, i.e. a comparison of the brightness

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of all generated directions can be achieved by suitable dimensioning of the summer 17.

FIG. 3 shows a modulator which, instead of the light deflectors 6 and 8, consists of a single, compact deflector cell ″. This contains a sound medium 18, on whose two mutually perpendicular surfaces each have a piezoelectric Sound transducer 19 is arranged. The sound medium 18 is surrounded by a sound absorber 20. The sound transducers 19 are of the control electronics 21 shown in Figure 2 with the controlled by the same control signal. A laser beam 22 impinging on the sound medium is deflected in such a way that at the same time a two-dimensional grid of laser beam directions arises. The compact acousto-optical cell in FIG. 3 can therefore replace the two line deflectors 6 and 8.

The operation of the linear data input converter will be described with reference to FIGS. 4 and 5. FIG. 4 shows a light point grid generated with the two acousto-optical modulators 6 and 8 with the associated shift of the light frequencies when controlled by a chain of 5 high-frequency oscillators with equidistantly graduated frequencies f ^ to f ^. As a result of the movement of the ultrasonic grating, however, these beams have a light frequency which is shifted by the respective sound frequency f and can therefore generally no longer be interfered with the reference beam.

It results that the frequency shift of a light beam through the first acousto-optical light deflector in the positive first order and is deflected into the negative first order by the second acousto-optic light deflector, completely is compensated and can interfere with the reference beam. All these light beam directions capable of interference lie on the diagonal row of the points of light directed to the zero order. All points of light lying outside this diagonal row

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cannot interfere with the reference beam. Only with A hologram recording is possible for the light points mentioned first.

FIG. 5 shows a reconstruction of a hologram recorded with the grid according to FIG. The oscillator with the frequency f was switched off.

Despite the creation of a two-dimensional light point grid So you get a linear data input converter for you holographic memory.

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Claims (4)

Claims 1.Linear data input converter for holographic data storage devices consisting of a laser transmitter, a beam splitter that splits the laser transmitter beam into an object beam and a reference beam, an acousto-optical modulator arranged in the object beam path, which spatially modulates the object beam with information fed in, and a hologram plate _} onto which the object beam and the reference beam are directed, characterized in that the modulator consists of a first and a second acousto-optical light deflector, the sound waves of which run perpendicular to one another _; and that the signal inputs of both light deflectors are connected via a summing circuit to a chain of high-frequency oscillators which can be switched on independently of one another or can be analogously modulated. 2. Linear data input transducer according to claim 1, characterized in that the first and the second acousto-optic Light deflectors together form a compact light deflector cell. 3. Linear data input converter according to claims 1 and 2 characterized by a narrow-band laser transmitter. 4. Linear data input converter according to claims 1 to 3 characterized in that a diaphragm is arranged in the beam path behind the modulator, which all but the light rays lying in the diagonal of the deflection directions fade out. VPA 9/710/4159 9826/0474 Read more